Bicycle Multi-Gear Cassette

ABSTRACT

A bicycle multi-gear cassette mountable to a wheel hub driver mechanism that includes truncated conical shell having a first opening proximate a small shell base and a second opening proximate a large shell base. The openings are coaxial with an axis of the shell. A plurality of toothed sprockets having different numbers of teeth are disposed on the shell and extend radially of the central axis. A torque load transmitting profile is configured on the shell proximate one of the small and large shell bases. A radial load transmitting profile is configured on the shell proximate one of the small and large shell bases. The shell, sprockets, and the load transmitting profiles embody a single piece.

BACKGROUND OF THE INVENTION

The present invention relates to bicycle multi-gear cassettes, and more particularly, to a multi-gear cassette that includes a truncated conical shell, a plurality of toothed sprockets disposed thereon, a torque load transmitting profile, and a radial load transmitting profile wherein the shell, sprockets and load transmitting profiles embody a single piece.

In a conventional multi-gear bicycle cassette, a plurality of discrete sprockets of variable diameter are arranged radially about an axis of a wheel hub. Each sprocket has a plurality of teeth spaced around its periphery for engaging a bicycle chain. The sprockets are mountable to a hub driver mechanism of the wheel hub to transfer pedaling forces from the bicycle chain to the wheel hub. In conventional designs, each sprocket may include a torque and radial load transmitting profile that mates to a corresponding profile on the hub driver mechanism. One disadvantage of this design is that the sprockets are acting individually in transmitting pedaling load from the chain, at one end, to the hub driver mechanism, at the other end, making the sprockets vulnerable to buckling and thus requiring thicker and heavier sprockets than desired.

In other devices, the individual sprockets may be attached to a plurality of carrier arms of an intermediate carrier, the arms receiving loading from the sprockets and transmitting it to the hub driver mechanism. Although the carrier may provide some lateral support to the sprockets, the carrier arms may themselves twist and flex under loading, also leading to buckling. Carriers with more rigid arms provide additional buckling resistance but come with a weight penalty. Beyond being resistant to buckling, carrier and non carrier-based multi-gear cassettes must be sufficiently rigid to resist excessive twisting and flexing under high impact pedaling forces to provide positive and direct load transmission to the wheel hub.

In the carrier cassettes described above, the discrete sprockets are attached to the carrier arms using bolts, mating threads, coupling projections or the like. These mechanical connections not only require additional material on the mating pieces, making the sprocket assembly heavier, but also introduce hole and thread features that weaken the mating parts and provide possible fatigue and fracture failure points on both the sprockets and carrier. Finally, such mechanical connections also introduce additional unwanted flexibility as they twist and deform under loading, softening load transmission from the chain to the hub driver mechanism.

Accordingly, a single-piece cassette according to the present invention avoids these design limitations by providing a rigid, buckling-resistant and lightweight load transmission path from the chain to the hub driver mechanism. In the prior devices having discrete sprockets, with or without intermediate carriers, the user may selectively replace one or more of the individual sprockets to customize the gear ratios of the cassette. Additionally, in a cassette design with discrete sprockets, the complex recess and cutout features on the face of the sprockets, as well as the precise chamfered tooth features, may be more readily and economically produced by stamping these features onto individual sprockets before assembly into a cassette. The present invention achieves both a rigid and lightweight design that is contrary to the teachings of these prior devices. By using a single-piece truncated hollow cone design that ignores the art-perceived need for discrete sprockets, the present invention represents far more than a structural difference over these prior devices.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a lightweight single-piece multi-gear cassette that rigidly transmits load from the bicycle chain to the hub driver mechanism.

The present invention provides a bicycle multi-gear cassette that generally includes a truncated conical shell, a plurality of toothed sprockets of variable diameter, a torque load transmitting profile, and a radial load transmitting profile wherein the shell, sprockets and load transmitting profiles embody a single piece. The sprockets are disposed on the shell and extend radially of the shell axis. The shell has a first opening proximate a small shell base and a second opening proximate a large shell base. The first and second openings are coaxial with an axis of the shell. A torque load transmitting profile is configured on the shell at the small shell base, at the large shell base, or at an axially-interior location on the shell proximate the small or large bases, or any combination thereof. Likewise, a radial load transmitting profile is configured at the small shell base, at the large shell base, or at an axially-interior location on the shell proximate the small or large bases, or any combination thereof. The radial and torque load transmitting profiles are positioned on the shell to stably support the cassette when mounted on the hub driver mechanism.

In one embodiment of the present invention, the shell may have a stepped configuration that includes a plurality of coaxial annular cylinders of variable diameter extending along the shell axis and a plurality of coaxial annular discs of variable diameter extending radially of the shell axis. The cylinders and discs are alternatingly arranged in a stepped sequence. A torque load transmitting profile is configured at or proximate an axially-outermost cylinder or disc or any combination thereof. Likewise, a radial load transmitting profile is configured at or proximate an axially-outermost cylinder or disc or any combination thereof. The cylinders, discs, sprockets and load transmitting profiles embody a single piece.

In another embodiment of the present invention, the shell may have a tapered configuration that includes a plurality of cone segments connecting the toothed sprockets. One or more of the cone segments are preferably oriented at an angle greater than 45 degrees from the shell axis. The cone segments, sprockets and load transmitting profiles embody a single piece.

In another embodiment of the present invention, the bicycle multi-gear cassette may include a cap member that is coupled to or proximate the large shell base and extends radially of the shell axis. The cap member includes a first opening coaxial with the shell axis for receiving a hub driver mechanism. The small shell base includes a second opening coaxial with the shell axis for receiving the hub driver mechanism. The torque load transmitting profile is configured at either the first or second openings, or both, for transmitting torque load to the hub driver mechanism. The radial load transmitting profile is configured at either the first or second openings, or both, for transmitting radial load to the hub driver mechanism.

These and other features and advantages of the present invention will be more fully understood from the following description of one or more embodiments of the invention, taken together with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIG. 1 is a front perspective view of a bicycle multi-gear cassette accordance to one embodiment of the present invention;

FIG. 2 is a rear perspective view of the bicycle multi-gear cassette of FIG. 1;

FIG. 3 is an exploded rear perspective view of the bicycle multi-gear cassette of FIG. 1 and a mating wheel hub;

FIG. 4 a is an exploded cross-sectional view of the bicycle multi-gear cassette of FIG. 1;

FIG. 4 b is an exploded cross-sectional view of an additional embodiment of the invention including a cap member attachable to interior portion of the shell;

FIG. 5 is an exploded cross-sectional view of an additional embodiment of a bicycle multi-gear cassette having a tapered shell;

FIG. 6 is a detailed cross-sectional view of a bicycle chain engaging a sprocket tooth of the bicycle multi-gear cassette of FIG. 5; and

FIG. 7 is a detailed cross-sectional view of a bicycle chain engaging a sprocket tooth of the bicycle multi-gear cassette of FIG. 1.

DETAILED DESCRIPTION

FIGS. 1-4 a and 7 illustrate a bicycle multi-gear or multi-sprocket cassette 10 according to one embodiment of the present invention. The sprocket cassette 10 generally includes a shell 12, a plurality of toothed sprockets 14, torque and radial load transmitting profiles 30, 38, 46, wherein the shell 12, toothed sprockets 14 and load transmitting profiles 30, 38, 46 embody a single piece. The single-piece construction may be achieved by any number of manufacturing processes, including for example, forming, casting, forging, or machining. The toothed sprockets 14 have different diameters and are disposed radially on the shell 12 relative to the shell axis 18. Each sprocket 14 includes a plurality of teeth 48 spaced around of the periphery of the sprocket 14 for engaging a bicycle chain 50 (FIGS. 6 and 7), each sprocket having a different number of teeth.

In the embodiment shown, the shell 12 has a stepped configuration; however the shell may assume any linear or nonlinear shape that properly positions the toothed sprockets. In the stepped embodiment shown, the shell 12 includes a plurality of coaxial annular cylinders 16 of variable diameter extending along a shell axis 18 and a plurality of coaxial annular discs 20 of variable diameter extending radially of the shell axis. The cylinders 16 and the discs 20 are alternatingly arranged in a stepped sequence to form the conical shell 12.

The shell 12 further includes a first opening 22 at a small shell base 24 and a second opening 26 at a large shell base 28. The first and second openings 22, 26 are coaxial with and substantially perpendicular to the shell axis 18. The shell 12 includes the torque and radial load transmitting profile 30 at the small shell base 24 on an inner surface of the shell 12 that engages a mating torque and radial transmitting profile 32, in this embodiment mating projections, disposed on an outer surface on a hub driver mechanism 34 of a wheel hub 36. The torque and radial load transmitting profile 38 is also located at the large shell base 28 on the inner surface of the shell that engages a mating load transmitting profile 40 on an outer surface of a removable cap member 42. The cap member 42 extends radially of the shell axis 18. In alternative embodiments, the cap member 42 may be coupled to a load transmitting profile disposed at an axially interior position of the shell 12 proximate the larger shell base 28 as shown in FIG. 4 b. In alternative embodiments, torque and radial load transmitting profiles need not exist at both the large and small shell bases 24, 28, so long as at least one torque load transmitting profile and at least one radial load transmitting profile exist on the shell 12. In an alternative embodiment, the cap member 42, shell 12, sprockets 14 and load transmitting profiles 30, 38,46 may embody a single piece. The cap member 42 includes a third opening 44 for receiving the hub driver mechanism 34 therethrough. The cap member 42 further includes a torque and radial load transmitting profile 46 at the third opening 44 on an inner surface of the cap member 42 that engages the mating torque and radial transmitting profile 32 on the hub driver body 34. Looking to the torque and radial transmitting profile 46 of the cap member 42, radial surfaces 41 transmit radial load to the hub driver mechanism 34, and torque surfaces 43 transmit torque load to the hub driver mechanism 34. Torque and radial load transmitting profiles 30, 38 on the shell 12 have similar radial and torque surfaces. In an embodiment where only a radial load is being transmitted through the load transmitting profile, torque surfaces 43 are eliminated.

In the embodiment of FIG. 5, a shell 52 includes a plurality of tapered cone segments 54 connecting the toothed sprockets 14 wherein the tapered cone segments 54, toothed sprockets 14 and load transmitting profiles 30, 38, 46 embody a single piece. In a preferred embodiment, the tapered cone segments 54 form an angle θ greater than 45 degrees to provide increased bending and buckling resistance to radially loading from the chain 50.

While this invention has been described by reference to particular embodiments, it should be understood that numerous changes could be made within the spirit and scope of the inventive concepts described. Accordingly, it is intended that the invention not be limited to the disclosed embodiment, but that it have the full scope permitted by the language of the following claims. 

1. A bicycle multi-gear cassette mountable to a wheel hub, the cassette comprising: a truncated conical shell having a first opening proximate a small shell base and a second opening proximate a large shell base, the openings coaxial with an axis of the shell; a plurality of toothed sprockets having different numbers of teeth disposed on the shell and extending radially of the central axis a torque load transmitting profile configured on the shell proximate one of the small and large shell bases; and a radial load transmitting profile configured on the shell proximate one of the small and large shell bases, wherein the shell, sprockets, and the load transmitting profiles embody a single piece.
 2. A bicycle multi-gear cassette according to claim 1, wherein the radial load transmitting profile is configured on the shell proximate the large shell base, the cassette further comprising: a cap member extending radially of the central axis coupled to the radial load transmitting profile proximate the large shell base, the cap member including a third opening coaxial with the shell axis for receiving the wheel hub, a second radial load transmitting profile configured at the third opening for transmitting radial load to the wheel hub, the first opening proximate the small shell base configured for receiving the wheel hub, a third radial load transmitting profile configured at the first opening for transmitting radial load to the wheel hub.
 3. A bicycle multi-gear cassette according to claim 2, wherein the torque load transmitting profile is configured on the shell proximate the large shell base, the cap member further comprising: a second torque load transmitting profile configured at the third opening for transmitting torque load to the wheel hub.
 4. A bicycle multi-gear cassette according to claim 2, wherein the shell, sprockets, loading transmitting profiles and cap member embody a single piece.
 5. A bicycle multi-gear cassette according to claim 1, wherein the truncated conical shell comprises: a plurality of coaxial annular cylinders of variable diameter extending along an axis; a plurality of coaxial annular discs of variable diameter extending radially of the axis; and the cylinders and discs alternatingly arranged in a stepped sequence.
 6. A bicycle multi-gear cassette according to claim 5, wherein the torque load transmitting profile is configured on one of the discs and cylinders, and the radial load transmitting profile is configured on one of the discs and cylinders.
 7. A bicycle multi-gear cassette according to claim 5, wherein one of the plurality of annular cylinders has a thickness smaller than a thickness of a base of an adjoining sprocket and one of the plurality of annular discs has a thickness smaller than the thickness of the base of the adjoining sprocket.
 8. A bicycle multi-gear cassette according to claim 1, wherein the truncated conical shell comprises a plurality of cone segments tapering relative to the shell axis.
 9. A bicycle multi-gear cassette according to claim 8, wherein a plurality of the cone segments form an angle greater than 45 degrees relative to the shell axis.
 10. A bicycle multi-gear cassette according to claim 9, wherein one of the plurality of cone segments has a thickness smaller than a thickness of a base of an adjoining sprocket.
 11. A bicycle multi-gear cassette according to claim 1, wherein the shell has a thickness smaller than a thickness of a base of one of the plurality of sprockets.
 12. A bicycle multi-gear cassette mountable to a wheel hub, the cassette comprising: a truncated conical shell having a first opening proximate a small shell base and a second opening proximate a large shell base, the openings coaxial with an axis of the shell; a cap member extending radially of the shell axis coupled to the large shell base for transmitting load therebetween; a plurality of toothed sprockets of variable diameter disposed on the shell and extending radially of the axis, the cap member including a third opening coaxial with the shell axis for receiving the wheel hub, the first opening coaxial with the axis for receiving the wheel hub; a torque load transmitting profile configured at one of the first and third openings for transmitting torque load to the wheel hub; and a radial load transmitting profile configured at one of the first and third openings for transmitting radial load to the wheel hub, wherein the shell, sprockets and load transmitting profiles embody a single piece.
 13. A bicycle multi-gear cassette according to claim 12, wherein the shell, sprockets, load transmitting profiles and cap member embody a single piece.
 14. A bicycle multi-gear cassette mountable to a wheel hub, the cassette comprising: truncated conical shell means having a first opening proximate a small shell base and a second opening proximate a large shell base, the openings coaxial with an axis of the shell; a plurality of toothed sprockets having different numbers of teeth disposed on the shell and extending radially of the central axis torque load transmitting means configured on the shell proximate one of the small and large shell bases; and radial load transmitting means configured on the shell proximate one of the small and large shell bases, wherein the shell means, sprockets, and the load transmitting means embody a single piece.
 15. A bicycle multi-gear cassette according to claim 14, wherein the radial load transmitting means is configured on the shell proximate the larger shell base, the cassette further comprising: cap member means extending radially of the central axis coupled to the radial load transmitting means proximate the large shell base, the cap member means including a third opening coaxial with the shell axis for receiving the wheel hub, second radial load transmitting means configured at the third opening for transmitting radial load to the wheel hub, the first opening proximate the small shell base configured for receiving the wheel hub, and third radial load transmitting means configured at the first opening for transmitting radial load to the wheel hub.
 16. A bicycle multi-gear cassette according to claim 15, wherein the torque transmitting means is configured on the shell proximate the large shell base, the cap member further comprising: second torque load transmitting means configured at the third opening for transmitting torque load to the wheel hub.
 17. A bicycle multi-gear cassette according to claim 15, wherein the shell means, sprockets, loading transmitting means and cap member means embody a single piece.
 18. A bicycle multi-gear cassette according to claim 1, wherein the wheel hub includes a hub driver mechanism.
 19. A bicycle multi-gear cassette according to claim 18, wherein the radial load transmitting profile is configured on the shell proximate the large shell base, the cassette further comprising: a cap member extending radially of the central axis coupled to the radial load transmitting profile proximate the large shell base, the cap member including a third opening coaxial with the shell axis for receiving the hub driver mechanism, a second radial load transmitting profile configured at the third opening for transmitting radial load to the hub driver mechanism, the first opening proximate the small shell base configured for receiving the hub driver mechanism, a third radial load transmitting profile configured at the first opening for transmitting radial load to the hub driver mechanism.
 20. A bicycle multi-gear cassette according to claim 19, wherein the torque load transmitting profile is configured on the shell proximate the large shell base, the cap member further comprising: a second torque load transmitting profile configured at the third opening for transmitting torque load to the hub driver mechanism.
 21. A bicycle multi-gear cassette according to claim 19, wherein the shell, sprockets, loading transmitting profiles and cap member embody a single piece.
 22. A bicycle multi-gear cassette according to claim 18, wherein the truncated conical shell comprises: a plurality of coaxial annular cylinders of variable diameter extending along an axis; a plurality of coaxial annular discs of variable diameter extending radially of the axis; and the cylinders and discs alternatingly arranged in a stepped sequence.
 23. A bicycle multi-gear cassette according to claim 22, wherein the torque load transmitting profile is configured on one of the discs and cylinders, and the radial load transmitting profile is configured on one of the discs and cylinders.
 24. A bicycle multi-gear cassette according to claim 22, wherein one of the plurality of annular cylinders has a thickness smaller than a thickness of a base of an adjoining sprocket and one of the plurality of annular discs has a thickness smaller than the thickness of the base of the adjoining sprocket.
 25. A bicycle multi-gear cassette according to claim 18, wherein the truncated conical shell comprises a plurality of cone segments tapering relative to the shell axis. 